Effects of an early‐life paraquat exposure on adult resistance to oxidative stress, plumage colour and sperm performance in a wild bird

Losdat, Sylvain; Blount, Jonathan D.; Marri, Viviana; Maronde, Lea; Richner, Heinz; Helfenstein, Fabrice

doi:10.1111/1365-2656.12822

Cited by 9 publications

(2 citation statements)

References 90 publications

(170 reference statements)

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“…However, results appear more conflicting when we come to the role of oxidative stress in determining lifespan or reproductive outcomes (e.g. Alonso-Alvarez et al, 2004Isaksson et al, 2011b;Noguera et al, 2012;Stier et al, 2012;Costantini, 2014;Beaulieu et al, 2015;Costantini and Dell'Omo, 2015;Blount et al, 2016;Costantini et al, 2016Costantini et al, , 2017Herborn et al, 2016;Colominas-Ciuró et al, 2017;Marasco et al, 2017;Merkling et al, 2017;Boonekamp et al, 2018;Casagrande and Hau, 2018;Losdat et al, 2018;Viblanc et al, 2018;Vágási et al, 2019). It is not trivial to assess the ecological and evolutionary relevance of oxidative stress, particularly in free-ranging animals.…”

Section: Introductionmentioning

confidence: 99%

Understanding diversity in oxidative status and oxidative stress: the opportunities and challenges ahead

Costantini

2019

Journal of Experimental Biology

144

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Oxidative stress may be of profound biological relevance. In this Commentary, I discuss some key issues faced by the emerging field of oxidative stress ecology, and seek to provide interpretations and solutions. First, I show that the way in which we define oxidative stress has far-reaching implications for the interpretation of results, and that we need to distinguish between (1) a biochemical definition in terms of the molecular outcomes of oxidative stress (e.g. generation of oxidative damage) and (2) a biological definition in terms of the fitness consequences for the organism (e.g. effects on fertility). Second, I discuss the dangers of comparing different tissues and markers. Third, I highlight the need to pay more attention to the cross-talk between oxidative stress and other important physiological costs and functions; this will allow us to better understand the mechanistic basis of fitness costs. Fourth, I propose the ‘redox signalling hypothesis’ of life history to complement the current ‘oxidative stress hypothesis’ of life history. The latter states that oxidative damage underlies trade-offs because it affects traits like growth, reproduction or cell senescence. By contrast, the redox signalling hypothesis states that a trade-off between signalling and biochemical oxidative stress underlies the regulation of reactive oxygen species production and their subsequent control. Finally, I critically appraise our current knowledge of oxidative stress ecology, highlighting key research themes and providing an optimistic overview of future opportunities for the discipline to yield considerable insight into the ecological and evolutionary meaning of oxidative stress.

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Section: Introductionmentioning

confidence: 99%

Understanding diversity in oxidative status and oxidative stress: the opportunities and challenges ahead

Costantini

2019

Journal of Experimental Biology

144

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“…Thermal stress during early life may directly influence oxidative status during adulthood if oxidative damage due to increased ROS production remains unrepaired, or if animals develop mechanisms to counteract oxidative stress under expected thermal conditions in the future (Losdat et al, 2018). Thermal stress experienced in early life may also indirectly cause delayed effects on cellular and physiological condition in adult life via compensatory growth (Metcalfe & Monaghan, 2001).…”

Section: Introductionmentioning

confidence: 99%

Carry‐over effects of early thermal conditions on somatic and germline oxidative damages are mediated by compensatory growth in sticklebacks

Kim

Noguera

Velando

2018

Journal of Animal Ecology

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Most studies of climate change impacts focus on the effects of summer temperatures, which can immediately impact fitness of breeders, but winter temperatures are expected to have a greater impact on development and growth of animals with long‐lasting consequences. Exposure to warmer temperatures can increase cellular oxidative damage in ectotherms. Yet, it is unknown whether thermal stress during early life has prolonged effects on oxidative status during adulthood. In an experiment using F1 fish originated from a wild three‐spined stickleback population at the southern edge of its European distribution, we examined whether experimental thermal conditions experienced in winter had carry‐over effects on oxidative status and telomere length, a marker of accumulated stress, in the soma and germline during adulthood. For this, oxidative DNA damage, enzymatic antioxidant activities and telomere length were measured three months after the termination of the temperature manipulation. In addition, we tested whether such delayed effects, if any, were due to individuals’ compensatory growth after experiencing unfavourable growth conditions in winter. Warm acclimation during winter induced increased levels of oxidative DNA damage in muscle and sperm and increased enzymatic antioxidant defences in muscle during the breeding season. Telomere length of adult fish was not influenced by thermal conditions experienced during early life. Winter temperature manipulation influenced fish to alter the temporal pattern of growth trajectories across the juvenile and adult stages. Fish reared in warm winter conditions grew at a slower rate than the controls during the period of temperature manipulation then accelerated body mass gain to catch up during the breeding season. Faster somatic growth during the breeding season incurred a higher cost in terms of oxidative damage in the warm‐treated individuals. For the first time, we experimentally show the long‐lasting detrimental effects of thermal stress on and the positive link between catch‐up growth and oxidative DNA damage in the soma and germline. Winter temperature increases due to climate change can reduce fertility and survival of fish by inducing catch‐up growth. The detrimental effects of winter climate change may accumulate across generations through the pre‐mutagenic DNA damage in the germline.

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Ecotoxicology of the herbicide paraquat: effects on wildlife and knowledge gaps

Donaher,

Van den Hurk

2023

Ecotoxicology

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Effects of an early‐life paraquat exposure on adult resistance to oxidative stress, plumage colour and sperm performance in a wild bird

Cited by 9 publications

References 90 publications

Understanding diversity in oxidative status and oxidative stress: the opportunities and challenges ahead

Understanding diversity in oxidative status and oxidative stress: the opportunities and challenges ahead

Carry‐over effects of early thermal conditions on somatic and germline oxidative damages are mediated by compensatory growth in sticklebacks

Ecotoxicology of the herbicide paraquat: effects on wildlife and knowledge gaps

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